about
Erythropoiesis-stimulating agents for anemia in rheumatoid arthritisErythropoiesis-stimulating agents for anemia in rheumatoid arthritisConserved proximal promoter elements control repulsive guidance molecule c/hemojuvelin (Hfe2) gene transcription in skeletal muscleFerritin for the clinicianCurcumin, a cancer chemopreventive and chemotherapeutic agent, is a biologically active iron chelatorIron Homeostasis in Health and DiseaseStructure and dynamics of drug carriers and their interaction with cellular receptors: focus on serum transferrinTransferrin-mediated cellular iron deliveryIron chelation therapy in myelodysplastic syndromes: where do we stand?Accelerated CCl4-induced liver fibrosis in Hjv-/- mice, associated with an oxidative burst and precocious profibrogenic gene expressionTransferrin Receptor Controls AMPA Receptor Trafficking Efficiency and Synaptic PlasticityHow the binding of human transferrin primes the transferrin receptor potentiating iron release at endosomal pHStructural and Molecular Characterization of Iron-sensing Hemerythrin-like Domain within F-box and Leucine-rich Repeat Protein 5 (FBXL5)Selective binding of RGMc/hemojuvelin, a key protein in systemic iron metabolism, to BMP-2 and neogeninThe type IV mucolipidosis-associated protein TRPML1 is an endolysosomal iron release channelIron behaving badly: inappropriate iron chelation as a major contributor to the aetiology of vascular and other progressive inflammatory and degenerative diseasesThe concentration of iron in real-world geogenic PM₁₀ is associated with increased inflammation and deficits in lung function in miceIdentification of a Steap3 endosomal targeting motif essential for normal iron metabolismNeoplastic transformation of rat liver epithelial cells is enhanced by non-transferrin-bound ironThe function of heme-regulated eIF2alpha kinase in murine iron homeostasis and macrophage maturationRedox, haem and CO in enzymatic catalysis and regulationAssembling the pieces.High density array screening to identify the genetic requirements for transition metal tolerance in Saccharomyces cerevisiae.Protein degradation and iron homeostasisInvestigation of the biophysical and cell biological properties of ferroportin, a multipass integral membrane protein iron exporter.Absorption of iron from ferritin is independent of heme iron and ferrous salts in women and rat intestinal segments.The role of iron in brain ageing and neurodegenerative disorders.Modulation of iron homeostasis in macrophages by bacterial intracellular pathogens.Effect of breastfeeding versus infant formula on iron status of infants with beta thalassemia major.Heme-mediated SPI-C induction promotes monocyte differentiation into iron-recycling macrophagesIron-regulatory proteins: molecular biology and pathophysiological implicationsMechanisms of brain iron transport: insight into neurodegeneration and CNS disorders.Systems analysis of iron metabolism: the network of iron pools and fluxesMechanisms of iron metabolism in Caenorhabditis elegansStudying disorders of vertebrate iron and heme metabolism using zebrafish.Hepcidin and the iron enigma in HCV infection.Minding metals: tailoring multifunctional chelating agents for neurodegenerative disease.Adjusting ferritin concentrations for inflammation: Biomarkers Reflecting Inflammation and Nutritional Determinants of Anemia (BRINDA) project.Hematological and biochemical markers of iron status in a male, young, physically active populationTargeting virulence: salmochelin modification tunes the antibacterial activity spectrum of β-lactams for pathogen-selective killing of Escherichia coli.
P2860
Q24200775-2E06372A-B28C-431A-A858-AC9ACC749D50Q24234260-205FA406-38D3-467C-B4B6-B812AFDD9039Q24569886-8A14E09F-F316-4B58-BAE1-0AD58BE8C913Q24642942-2BC72039-9304-4B77-9FF1-EE7B686F0B17Q24652363-714D0380-CE32-4510-BD89-08B0E9678119Q26775146-F9DD7C15-0D75-4F0A-889B-1BB315E0DC77Q26853427-84368C76-ED77-4DD4-988E-3EECDD9F3D9AQ27004133-2B72F60F-4153-4941-8470-2072989DC4CDQ27011747-6EE38E65-ED32-4F4D-A6C7-05DF9988FC67Q27319418-D37D143D-1825-4181-846F-42ED67E7462FQ27349241-A47FC930-ECF8-4C81-8EB6-B92D11AB0DA0Q27670998-44A28F67-510B-485B-AF59-A132522EB267Q27676781-79C444C1-6E66-43ED-B199-DCDF60416901Q28269309-8FA5B95C-B7B2-45AC-AEA4-935BE5A98275Q28294133-021599B7-56FF-41CF-8EBC-AFB9BEA300A2Q28388335-3BF78DB3-B653-4FEC-A35D-B30AC6368110Q28396750-0497A332-FED1-45DD-9E09-C0B9B92AA80BQ28512362-EBE81DC7-6F7D-4129-A821-49FD6B20B971Q28570714-623E6858-4428-4C86-91F3-71F55F8977C6Q28592020-8E6298E9-2CB9-4A66-B2EB-A0ED2FA0DAA0Q28709561-5E4492D8-B7FF-4340-9A7A-280BAB73DCD5Q30367790-1027855A-EE73-486D-AEA2-4209CA639D1EQ30398332-047DFFC2-4FAF-4381-A3FD-B4F9EBD59BF3Q30413289-FEA77C9D-B193-4446-9843-962A6EB05716Q30487384-CF6832B4-8CDA-41D9-A6C0-1D85D7612CE9Q30505284-6A0873B4-9B75-4BEE-9802-CE3409D29C79Q30852753-94DF7D31-5866-4397-A0EE-EEEC564E45C0Q33534484-9E2A0A26-CC03-49A7-AF54-A4D6F25FFA89Q33568737-1CDCA194-5AC7-4F57-899F-A7645D94044DQ33570011-95839303-9CE8-475F-AB63-B4D538B00893Q33610411-2A8828FD-EA4A-4F06-86AD-542A5B6AF735Q33616799-B776D162-04F9-45CB-92EC-EBC1F50DBD61Q33655670-8976BF81-D9B1-4CBD-87F4-F4B0B128B264Q33658871-FB1FD47C-F5B2-466D-947E-3A00BDF43A6EQ33758533-C02B49FC-1D4E-41CF-BD67-83233B0E316AQ33779089-FA392223-ABDA-4FDD-925E-08AB7AAE1FD3Q33813567-32961819-1FF0-4CA4-8CF5-98F6D744FE01Q33852303-67D54BBA-4484-4117-A52B-A06D3B7F01D2Q33876754-F7433DFD-A80B-4221-A39E-5A92A9E88208Q33877981-058F46AE-25D9-4D4C-A32D-4C9A7E4ACD9F
P2860
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Iron homeostasis.
@en
type
label
Iron homeostasis.
@en
prefLabel
Iron homeostasis.
@en
P1476
Iron homeostasis.
@en
P2093
Paul J Schmidt
P356
10.1146/ANNUREV.PHYSIOL.69.031905.164337
P577
2007-01-01T00:00:00Z